SE508846C2 - Supply air with hole provided at which nozzles and slots are provided - Google Patents

Abstract

PCT No. PCT/SE97/00388 Sec. 371 Date Aug. 19, 1998 Sec. 102(e) Date Aug. 19, 1998 PCT Filed Mar. 6, 1997 PCT Pub. No. WO97/34113 PCT Pub. Date Sep. 18, 1997A supply air terminal device (1) of box-like or screen-like construction has a front wall (5) in which there are disposed a plurality of groups (10) of slots (7) with the groups and the slots in each group mutually spaced apart. Each group of slots is allocated a nozzle module (11) mounted on the inside of the wall (5). Each nozzle module (11) includes a number of nozzles (12) corresponding to the number of slots, wherein each nozzle functions to repeatedly deflect the part-flows (B) through an angle of 90 DEG from a delivered main flow. To this end, each nozzle (12) of a nozzle module (11) carries at its ends curved deflecting parts (12b) which project progressively further out in the direction of the main flow. The deflected part-flows mutually collide and exit with a low impulse through the slots (7) allocated to respective nozzles (12). The invention also relates to a nozzle module for a supply air terminal device (1) of the aforesaid kind.

Description

508 846 2 must be replaced at regular intervals, which means both a cumbersome and expensive solution.

Further examples of the state of the art can be found in WO 90/02912 (Papula Rein Lathela), DE, C, 4 428 655 (Erwin Müller) and DE, C, 4 026 529 (H. Krantz-TKT).

Object of the invention An object of the invention is to provide an improved supply air device which without the use of filters enables an efficient mixing of air from the room and allows efficient, draft-free supply of temperate air to the room.

Another object is to provide a compact supply air device which in a preferred embodiment allows simple individual adaptation of the direction of the air from the device.

A further object is to provide a supply air device which has a more even air distribution from the nozzle openings of the supply air device than could be achieved with hitherto known supply air devices.

According to another aspect, it is an object to provide a nozzle module for a supply air device of the type indicated, which constitutes a unit separate from the main part of the supply air device, which is easily applicable in the device, can be manufactured as a mass article in large series and which , in a preferred embodiment, allows simple control within wide limits of the air flowing out of the supply air device.

Brief description of the invention These and other objects are fulfilled by a supply air device according to the invention which is of the type stated above and has the characteristics stated in the characterizing part of claim 1.

The advantages offered by the invention are conditioned by the nozzle modules located immediately behind the slot holes, which by their design capture equal partial flows to each slot hole.

These partial flows are redirected about 90 ° twice before the passage of each slot hole and due to their shape and location a 3 sus 846 good mixture of room air is obtained in the fresh air supplied via the supply air device.

Because the partial flows redirected by the guide rails collide before the passage of the slot holes, they depart through them with a low impulse, which ensures the desired desired tensile-free supply.

In practice, it is preferred that the nozzle module for the supply air device has the characteristics specified in claim 2. Each slot hole is then passed by a controlled partial flow which becomes the same size for all slot-shaped openings.

In addition, it is preferred that between two successive nozzles in a nozzle module there is a partition wall which helps to direct the collided partial flows out through the adjacent slot hole perpendicular to the slot provided with a slot.

In practice, it is further preferred that the nozzle modules are displaceable in the longitudinal direction of the slot holes and more specifically so that the nozzle modules from a central position are displaceable in the direction of both ends of the slot holes for direction of the air jets about 90 ° relative to the flow direction in the central position.

If the nozzle module is thus displaced towards an end position, the air jets on this side are throttled while the air flow increases on the opposite side. The air jets are then linked to the throttled side. Due to this displacement possibility, air jets emanating from the supply air device can be directed continuously for almost i90 °.

The slit-shaped holes are a prerequisite for the possibility of being able to direct the air within the specified large area. There is no equivalent with round holes resp. nozzles equipped with supply air devices where the air is controlled mainly in dependence on the plate thickness of the supply air device in relation to the actual hole diameter.

Furthermore, it is preferred in practice that the nozzle modules at the ends have resilient snap means for releasable fixation in the first resp. the last slot in a group. In this way, the nozzle modules can also be easily dismantled, e.g. for recycling 508 84-6 4 or exchange. The snap means may comprise finger-actuable parts intended to be actuated at the lateral displacement of the nozzle modules for setting the desired outflow direction.

In order to facilitate the operation of the nozzle modules, several successive groups of such may be joined, e.g. of plates extending at the sides, so that simultaneous lateral displacement of several nozzle modules is allowed.

The number of slot holes in each group as well as the dimensions of the slot holes can vary within relatively wide limits. In order to create a standard, especially to facilitate the manufacture of the nozzle modules, a few different type sizes can be determined for different areas of use.

A type size that has been found to be appropriate is a number of twelve slot holes for each group, each with the dimensions 3 x 35 mm.

The shape of the supply air device itself can also vary within wide limits. It can thus have a completely or partially round shape, have the shape of a box with flat and / or curved side surfaces and with a wide cross-sectional shape varying within wide limits. Alternatively, the supply air diffuser may be in the form of a comparatively compact screen, whereby the even air distribution and efficient air deflection which the invention offers advantageously contributes to the compact construction of the supply air diffuser.

A supply air device according to the invention suitably has a nozzle module, which nozzle module has the features specified in claim 9.

The body of the nozzle module can also have a rear wall which preferably comprises two parts extending at an angle to each other, projecting in front of the side elements.

A nozzle module of the specified type can be located inside the supply air device itself so that the nozzles are substantially invisible from the outside, whereby an aesthetic advantage is gained. Another advantage is its 508,846 acoustic effect through its labyrinth design which reduces direct radiation of sound from the ventilation system. 5 Additional characteristics and advantages of a supply air device resp. a nozzle module according to the invention will appear from the following description of some embodiments thereof.

The description is made in connection with the attached drawings.

Brief description of the drawing figures Figs. 1-4 are perspective views of some different types of supply air devices according to the invention, where the front wall has a number of groups of slot holes.

Fig. 5 is a front perspective view of a nozzle module for a supply air device according to the invention.

Fig. 6 is a rear perspective view of the nozzle module of Fig. 5.

Fig. 7 is a front view of a nozzle module according to Figs. 5 and 6 with marked main and partial flows for deflection thereof.

Fig. 8 is a plan view through two adjacent slot openings with associated nozzles which form parts of a nozzle module according to Figs.

Fig. 9 is a view corresponding to Fig. 8, after displacement of the nozzle module for lateral deflection of the flow delivered via the slot opening.

Description of preferred embodiments Figs. 1-3 give examples of supply air diffusers 1 of box shape, wherein Fig. 1 shows a box with a flat rear wall, flat narrow side walls and a curved front wall, so that the box in cross section acquires approximately circular sector shape.

Fig. 2 is a box with curved front and rear walls and substantially elliptical cross-sectional shape. Fig. 3 shows an example of a box with approximately circular sector-shaped cross-section and curved front wall.

Fig. 4 gives an example of a supply air diffuser in the form of a parallelepiped screen with flat walls.

All supply air devices comprise a body with a top wall 3 and a bottom wall 4 and a front wall 5 provided with a number of holes or openings 7 for discharging air supplied via a connection 8 to the device's internal supply to a room.

In all the embodiments shown in Figs. 1-4, the main flow direction of the supplied air is vertically downwards through the supply air device.

A supply air device according to the invention does not, however, have to be set up on a substrate but can e.g. be arranged with a horizontal axis, ie so that the main flow direction of the supplied air also becomes horizontal.

The front wall 5 of all supply air devices in Figs. 1-4 has a number of groups 10 of slot holes 7, the holes 7 in one group being located one after the other parallel to the main flow direction with a distance between each group 10 as well in said parallel direction as perpendicular thereto.

In the supply air devices shown in Figs. 1-4, each group 10 each comprises six slot holes 7.

Each such group 10 of slot holes 7 is assigned to a nozzle module 11 of the type shown in Figs. 5 and 6 arranged on the inside of the wall 5.

Each such nozzle module 11 has a number of nozzles 12 corresponding to the number of slot holes, i.e. in the present case six such nozzles 12.

As can be seen from Figs. 5-7, one nozzle 12 following the other has a nozzle module 11 perpendicular to the main flow direction A, progressively longer projecting curved deflection parts 12b. These curved deflection parts 12b are arranged at the ends of the central, flat main part 12a of the respective nozzle. Due to the indicated shape, each nozzle 12 of a nozzle module 11 can capture and repeatedly redirect subflows B from a main flow A, namely first from the main flow direction perpendicular thereto towards the center of the nozzle and then provide further deflection 90 ° - at the shown the embodiment in the horizontal direction outwards through the respective slot holes 7 - as a result of the diverted partial flows B to each nozzle colliding. As shown in Fig. 8, they will then emit outwards with low impulse through the slot 7 cooperating with the nozzle.

As can be seen from Fig. 8, due to the shape and location of the slot holes, good mixing of room air is obtained in the air supplied via the supply air device.

Between two successive nozzles 12 in a nozzle module 11 there is a partition wall 11a which helps to direct the colliding partial flows B out through the adjacent slot hole 7.

The nozzle modules 11 are provided at the ends with resilient snap means 11b for releasable fixation in the first resp. the last slot 7 in the group 10. These snap means 11b project into the air flow in the device and compensate for any velocity differences in the main flow.

These snap means 11b are provided with finger-actuating parts 11c by means of which lateral displacement of the nozzle modules 11 can be effected.

By such lateral displacement, the air jets departing from the slot holes 7 can be directed: 90 ° from the perpendicular direction straight out from the front wall 5, when the nozzle module 11 is in its central position. Fig. 9 shows the two adjacent nozzles 12 displaced to the left, the air jet B 'being partially throttled while the air flow on the opposite side has increased, which is illustrated by the larger arrows B ". 508 846 8 The spacing between the two adjacent nozzles 12 in Figs. 8 and 9 facilitates the mixing of room air.

As can be seen from Figs. 5 and 6, the nozzle modules 11 consist of a frame with parallel elements 11d extending at the sides of the module and a rear wall 11e which comprises two parts extending at an angle to each other, projecting in front of the side elements. This body carries the successive nozzles 12, each of which has a central flat part 12a which extends perpendicular to the side elements 11d and projects in front of them and at the ends has opposite curved end portions which form the deflection means 11a. Between the nozzles 12 there are partitions 11a connected to the side elements 11d which are thus parallel to the central flat parts 12a of the nozzles. The labyrinth design of the nozzle modules means that they significantly reduce the emission of noise generated in the ventilation system.

As stated above, the deflection means 12b to one of the other nozzles 12 following one another in the main flow direction are located progressively longer projecting from the respective central part 12a.

The slot holes 7 can e.g. have the dimensions 3 x 35 mm. The distance between each group of 10 slot holes 7 can e.g. be 20 mm, which gives the room air "free passage" up to all exhaust openings.

Claims (10)

š08 846 Patentkrav Supply air device of box or screen shape comprising a frame with a top and a bottom wall (3; 4) and extending front and rear therebetween and optionally side walls, of which at least one front wall (5) is provided with a number of holes or openings (7) for discharging air supplied via a connection (8) to the inner (1) of the device (1) to a room, wherein in the area of the holes (7) there are nozzles (12) or nozzles for trapping and deflecting in a main flow direction (A) through the partial passages (B) passing through the device, characterized in that the front wall (5) has a number of groups (10) of slot holes (7), the slot holes (7) in a group being located one after the second in parallel with the main flow direction with a distance between each group (10) both in said parallel direction and perpendicular thereto, b) that each group (10) slot holes (7) are associated with a nozzle module (11) arranged on the inside of the wall (5) ) with the number of nozzles (12) corresponding to the number of slot holes arranged to t capture each slot (7) in a group (10) and emit equal sub-flows (B), and c) that each nozzle (12) of a nozzle module (11) is arranged to capture and repeatedly redirect sub-flows ( B), namely from the main flow direction perpendicular thereto towards the center of the nozzle due to the curvature of two opposite, nozzle associated diverting parts (12b) and then a further 90 ° due to sub-flows (B) diverted via these diverting parts impulse travels outwards through the respective slot associated with the slot (7). Supply air diffuser according to claim 1, characterized in that one of the following nozzles (12) in a nozzle module (11) has progressively longer projecting curved deflection parts (l2b) perpendicular to the main flow direction. V __? _? 508 846 10 3. characterized in that between two (11) there is a partition wall (11a) which helps to direct the collided partial flows (B) out through the adjacent slot hole (7) perpendicular to the slot-provided wall (5). Supply air diffuser according to claim 2, successive nozzles (12) in a nozzle module Supply air diffuser according to one of claims 1-3, characterized in that the nozzle modules (11) are displaceable in 4. t e c k n a t a v the longitudinal direction of the slot holes (7). Supply air diffuser according to claim 4, characterized in that the nozzle modules (II) from a central position are displaceable in the direction of both ends of the slot holes (7) for directing the air jets approx. 90 ° relative to the outflow direction in the central position. Supply air diffuser according to one of Claims 1 to 5, characterized in that the nozzle modules at the ends have a spring 11b) for releasable fixing in the first resp. 6. t e c k n a t a v arious snap means (the last slot hole (7) in a group (10), which snap means also serve to compensate for any velocity differences in the main flow. Supply air diffusers according to claim 6, according to claim 4 or 5, characterized by finger-actuable parts (11c) intended to be actuated during nozzle mode - the snap means (11b) comprising the lateral displacement of the clays. 8. k ä n n e t e c k - n a t a v the following groups (10) of slot holes (7) are joined, for simultaneous lateral displacement. Supply air diffuser according to claim 6 or 7, that the nozzle modules (11) to several on each other e.g. of plates extending at the sides, Supply air diffuser according to one of Claims 1 to 8, characterized in that the nozzle module (11) comprises a) a body which has parallel elements (11d) extending at the sides of the module, b) one plane of the nozzle following one another successively. (1 (12) has a center 2a) which extends perpendicular to the side elements 11s 846 and projects in front of these and has opposite curved end portions which form the deflection parts (12b). Supply air diffuser according to claim 9, characterized in that the body has a rear wall (lle) which preferably comprises two parts extending at an angle to each other, projecting in front of the side elements (lld).